US2743360A - Pulse-length switching circuit - Google Patents

Description

April 24, 1956 R. s. STANTON E-rAL 2,743,360

.I PULSE-LENGTH SWITCHING CIRCUIT Filed Feb. 2, 1953 s INVENToRs,

ff-/FL Y0U/vf BY fluff# .52 fam/ra PULSE-LENGTH SWITC G CRCUIT Russell S. Stanton and George Yucht, Los Angeles, Calif.; said Yucht, now by change of name George L. Young, assignors, by mesne assignments, to Hughes Aircraft Company, a corporation of Delaware Application February 2, 1953, Serial No. 334,612 6 Claims. (Cl. Z50-27) This invention relates to switching circuits and more particularly to a circuit for automatically changing Ithe time duration of the pulses produced by a line-type modulator of a radar system.

Conventional radar search and tracking systems generally radiate a pulse of long duration for the long distance search phase of their operation and radiate a pulse of short duration for the tracking phase of operation and for Search phases requiring high definition. inasmuch as the duty cycle of the transmitter of the radar system should preferably remain substantially constant, it is also desirable that the repetition rate of the radiated pulses be changed in accordance with changes of the length or duration of the radiated pulses.

In general, line-type modulators developing high-voltage output pulses are used in such radar systems and comprise a network simulating a transmission line, the electrical length of which de-termines the duration or length of the pulse formed by it. This network is charged from a source of direct potential through a lter circuit and a charging inductor to a potential that is approximately twice the magnitude of the direct potential applied thereto. In order to vary the pulse length, it is necessary .to switch networks simulating different lengths of transmission line. The principal requirement of a switching circuit for effecting variation of the pulse length is that the current in the charging inductance must be negligible at the time -the networks are switched. Excessive transient voltages will be developed as a result of the energy stored in the magnetic field of the charging inductance if this ycondition s not met.

The switching circuit of the present invention reduces the current in the charging inductance to substantially zero before switching the networks by deenergizing the source of direct potential from which the transmission line networks are charged and by providing means .to render a gas tube switch such as a thyratron conductive during a predetermined interval of time immediately prior to the switching from one network to another in order to discharge the energy in the filter circuit connected to the direct potential source.

-An advantage of the switching circuit of the present invention is that .a thyratron is used to discharge the energy in the tilter circuit very rapidly, thereby making it unnecessary to use a high-voltage shorting switch, bleeder resistors, or a time-delay relay such as are provided in some prior lart switching circuits for pulse modulators. Another advantage of the circuit of the present invention is that the time required to complete .a switching cycle is a function only of the operating time of seve'ral conventional relays operating in succession and therefore may bejrel'atively short. In addition to the vforegoing, 4the operation of the pulse modulator switching circuit is independent of the .pulse duration, the pulse repe- -tition'rate andthe magnitude of the potential charging the network. Furthermore, the networks may be switched at' any time during'the modulator charging cycle.

Patented Apr. 24, 1956 ICC It is -therefore an object ot' this invention to provide an improved switching circuit for a pulse modulator.

Another object of this invention is to provide `a-pulse modulator switching circuit which operates independently of the pulse length, the pulse repetition rate, the magnitude of the voltage charging the transmission line ne'twork, and of the instant of time switching from one transmission line network to Ianother is initiated.

A further object of the invention is to provide a switching circuit for a pulse modulator capable of completing a switching cycle during the relatively short time required for the operation of several conventional relays openating in succession.

A still further object of this invention is to provide a switching circuit for automatically changing the pulse length of a line-type modulator including a thyratron switch wherein the current in the charging inductor is reduced to substantially zero by discharging the energy of the filter circuit through the thynatron switch that is rendered `conductive immediately prior to the switching operation.

The novel features which are believed to be characteristic of the invention, both as to its organization and method of operation, together with fur-ther objects and advantage-s thereof, will be -better understood from the following description considered in connection with the accompanying drawing, in which an embodiment of the invention is illustrated by way of example. It is to be expressly undersood, however, -that :the drawing is for the purpose of illustration and description only, and is not intended as a denition of the limits of the invention.

The single figure of the drawing is `a schematic diagram of the circuit ofthe present invention.

Referring now to the drawing, there is shown a con-v ventional line-type modulator generally .comprising a highvoltage rectier circuit 12, a lilter circuit 14, a charging inductor 16, a charging diode 18, a first pulse forming network 2l) for forming a pulse of length or duration TA, another pulse forming network 22 for forming a pulse of duration TB, and a gas tube switch such as, for example, a hydrogen thyratron 24. Pulse forming networks 20 and 22 simulate transmission lines of different electrical lengths and may comprise a two-terminal network formed by a series inductance having several capacitors shunted between equally spaced taps on the series inductance and a common junction. A shun-t diode 23 is connected `from the anode of thyratron 24 through a current limiting resistor 25 to ground so as to discharge any negative poten-tial appearing on .the anode of thyratron 24. The line-type modulator -is connected through a pulse transformer 25 to a magnetron 28,'which is shown schematically. Pulse generators 30 and 32 provide sources ot periodic pulses having repetition rates A and B, respectively, which are utilized to trigger thyratron 24 thereby 4to develop output pulses having corresponding pulse lengths TAand TB, respectively.

The switching circuit of the present invention employs relays 34, 36, 38, 40 yand 42. Relay 34 functions to connect and disconnect power on to rectifier circuit 12, relay 40 provides for switching between the pulse forming networks 20 and 22, while relay 42 provides for switching between pulse'generators 30 yand 32; Relays 36 and' 38 are control relays which provide the necessary sequence of operation. The foregoing line-type modulator is con` a general'description of the over-.

which-is connected to ground. The other end of thel coil o'f relay- 34 is connected by a lead 48 through a nor;

malty closed contactwarmf sofrelay 36 and a normally closed.. .contact arm. 52 of. relay.. 3S` .to.,gro.und.. ...111..order to clarify the explanation o-ilthe functioning of the disclosed circuit, switch 44 isshown in 'the on position for wthe modnlatorythuseenergizing frel'ay.-'4, oausingl its contact-arms54,f55,5 56.',an'd'2577 lto nappear Iin#positions corresponding: tto lth'e energized.'oonditionsof :relay 34. Rel'ays', I'2'',='11tl and 242rare shown ainda deenergized condition.

lflhereoreas previously explained, thevc'losingxofoffeon ing 'potential is impressed across primary winding '62 of transformer .64, Vthe niid-.point--of 'secondary winding 65 is grounded.

Junctionl l66 is connected to filter circuit 14 which comprises a series inductor 68 and .al shunt capacitor`70. A smoothed and rectified ypositive output .voltage appears at `a"jur1ctionv T72 at lthe output of 'filter 14, which is connected through charging .inductor 16, charging diode 18, and ajunction 73. .to a contact arm 74..of relay40, which may 'be selectively connected .to eitherone of pulse formingl networks or .22. Charging diode v18 is .poled so .as to ypermit .the -chargingof a pulse forming :network ina A positive direction yonly. As .a "result-.of resonance by inductor=16 'with the capacitance ofinetwork 20 lor 22, Vthe potential of junction ,.73 `will'increase to approximately double they positive voltage at .junction .-7-2. When fthe potential across-pulseformingnetwork 20 reaches its highest point, the charging ,indnctorV .16 will 'be veffectively disconnected from'the pulse forming network 20 bychargingdiode :18.

l -l'n normal operation, the'rnodulator isf-triggered by Z9. this switching lis accomplished by rst removing the ex- ,.ieitaton...f.ron1v .primary winding. .62A of. .rectier..cir.cuit.12.

Simultaneously, thyratron 24 is rendered conducting so as to discharge theY energy in capacitor 70 of filter circuit 14 through charging inductor 16', charging diode 18, and thyratron 24. During this pulse length switching operation, it'is essentiallthat the current through charging .inductor`. 16 be` reduced .to Ya.negligiblevalue; otherwise extremely high transient voltages can result at junctionl ,'73 during `the.;travel-.tirne of: contact-'farml 74 relay 49. The time interval required'to discharge fthe energy inf capacitor 570'o'f 'filter circuit 14 is ofmu'ch longer duration than 'the time required to discharge the energy v`in pulse.formingnetwork 20,".during .its znormal operation and is generally of sutlicient duration to allow appreciable current to commence :flowing through charging inductor 16. Hence, itis necessary to remove the excitation on primary winding 62 so that capacitor 70 may be `completely .adisoharged; priorl `tol switchinglfrom pulse ,forming network 220 tto pulse 'iforrning network 22,411 order lto `have ynegligible 'current'-lowing -through charging inductor 16 at the time of switching the networks. 'Therefore,:after the .energy lstored lin capacitor "10A-'has'. been dissipated,ithe second pulseforming ynetwork 22 yand-pulse generator '32 are switchedinthecircuit. Finally,f1excita Y tion is rcapplied .in primarywinding-62 of rectifier 2circuit 112.

One example'of the manner in which the thyratron24 l mayv be rendered conductive for -a sufficient Alength of time pulses 'from pulse 1generator-30 vapplied through contact v.

arm 76 ofrelay -42 .tothe 'grid ofwthyratron .24. When ionization'occursn thyratron 24inzresponseto a triggering pulse, the :potential at junction 73 is :effectively clamped to .ground vthrough the very :low resistance 'of thyratron'24, causing `the common junction: of theshunt capacitors of the pulse formingrnetworkx201to;go sharply negative, thereby to discharge a negativefpulse 'through pulse transformer .'26 .fand 4.to limpress .it von magnetron 128.

II-Ience, during normal `:operation-'of :the modulator,` a triggeringy pulse .fappliedwto'wthyratronl24 -:renders rit conducting, .thereby causingthe `pulse forming .network .to .discharge 'through pulse transformer. 26. Charging :inductor 16. prevents:appreciable'fcurrent f rom'owing through filter .circuit 14'during the 'shortintervalLoftime'required for fthis discharge :to take place. -=It will .also -be found that occasional sparking '.ofizmagnetron r28 vwill fcause ra negative pulse 'to' be 'reflected from `'pulse rtransformer' .'26

which .would-haveaatendencyto charge the pulseforming n lnetwork 20 ina negative-direction, thus .causing Lthe network f20 :to be subsequently :charged to ;a Lliigher'voltage than-that which iit-=was designedrttogproduce In order to preventthis, shuntvdiodei .dischargesaany':negative voltagev appearing .on :network'ljto ground-.through 1currentv limiting. resistor `.25,1 thereby improving `'the Iout- Vput .stability of Nthey system.

Quite frequently, as previouslyffexplained;:in `present 'day radar systems, itisfdesirablefto :change the .time @durationordength of .the transmittedpulses. Changing the durationfofithe transmitted pulsesfinfa line-type modula.

tor, ,may- .involve .switching from .one jpulse. iorrningnnet-l work .toianothen Inzzthe circuitof .thepresentinyentiom and Acommencing at a desired instant of time, is shown in the drawing. lThat is, a'potential-source-84 iscaused to charge a capacitor to a positive voltage through-"a resistor v82. The fvoltage -of potential Isource 84 'must 'fbe greater 'than the grid-cathode ionization Apotential of thyratron '24. Thyratron 24 is then .renderedconductive when contact arm 54ot` relay 34 switches resistor 82 from its connectionto potential source 84to the grid of thyratron 24, therebyenabling the positive lcharge on capacitorBO to vdischarge through'resistor 82 and-thence from the grid to thecathode of `thyratron 24 and to ground. Once fthe gasA in thyratron 24 has become ionized, 'the'tube' Will, off'course, Aremain jconductive 'until the*-platetcathode potential ofv the tube falls below a certain critical value.

The* time constant of capacitor'80 andresistor 82 should be of such va magnitude las to renderthe thyratron'24 conducting 'for a 'sufficiently .long lduration, in order to iallow current lto @commence `flowing through Vcharging inductol 16, diode 18 and thyratron24 to ground. Representative valuesfor resistor 82 may be of the .order of 1500 ohms and' for capacitor .'80 may be of the order 6i one microfarad when 'charging inductor '16 is of the. order ve henrys Hence the Atimeconstant .of .network/80, 82 is 500 microseconds In the switching .circuitjshownin .thefdrawing .changing from pulse `length Tato pulselength .Tn.is...automatic once it is initiated. manually by .the Yclosing ofswitch 86. The .closing .of switch 86 energizesrelay .36 .by ,completing the connection of its coil acrosspotentiahsource 46 over lead .88.y The energization of relay v36 .causes contact-.arm49 .to lopen .the ground return of .the.coi1.of relay .34 through lead 48, contact 49 of .relay 36.and.t:on tact -52 of .relay 38, thus .causing .relay 134. .to,.drop.out. Contactarm 56 of` frelay 34 .then opens, removingethe excitation .from primary winding 52 -of .transformer-n64 of .the .high voltage .rectifier circuit.12. Contact of .relayft .simultaneously connects .resistor-1.82 .mathe grid of thyratron 24,thus-v enabling r.the .charge tongpieitorl .to discharge. through .resistorwl ffrom;-.the:grid to theicathode of :thyratron-24mm 4thence tog-ground, thereby .ionizing VV.the ithy-ratron -24 and, :rendered it conductive. This allows .capacitor vv'l0 ato zdischaggefrhrogsh charging inductor. lgchargingzdiode 18 and thyratron 24 ,togiground .Afterthe-.voltage ionncapacitnr .1Q-thas charging inductor 16 and the pulse forming networks may. be switched without any detrimental eects.

Energization of relay 36 also closes contact arms 50 and 51. Thus, one end of the coil of relay 38 is connected to potential source 46 through contact arm 51 and lead 88. However, relay 38 is not energized until relay 34 drops out because the other end of the coil of relay 38 is connected through contact arm 50, over lead 90 to contact arm 55 of relay 34 and thence to ground, the contact arm 55 remaining open until relay 34 drops out. Hence, relay.38 will be energized as soon as relay 34 drops out, which occurs after relay 36 is energized. The contact arm 53 of relay 38 acts as a holding contact for relay 38 and connects one end of the coil of relay 38 directly to ground when relay 38 pulls in, thereby shunting the path to ground through contact arm 50 of relay 36, lead 90 and contact arm 55 of relay 34. In addition to the above, the energization of relay 38 causes contact arm 47 to close, which energizes relays 40 and 42 by completing the connection of their respective coils across potential source 46 through lead 88, contact arm 47 and lead 89 to ground. Contact arms 74 and 76 of relays 40 and 42, respectively, disconnect pulse forming network 2t) and pulse generator 30 from the modulator circuit-and connect, instead, pulse forming network 22 and pulse generator 32. Simultaneously with the above, contact arm S2 of relay 38 completes the ground connection of the coil of relaly 34 through contactv arm 49 of relay 36 and lead 48, thus causing it to pull in. The energization of relay 34 disconnects resistor 82 from the grid of thyratron 24 and reapplies excitation to primary winding 62 by means of contact arms 54 and 56, respectively. At this stage, the modulator is back in operation with pulse forming network 22 and pulse generator 32, thereby producing pulses of time duration TB and of repetition rate B. It is to be noted from the foregoing description, that the time allowed for discharging the energy stored in capacitor 70 of filter 14 is equal to the operation time for relay 38, while the time actually required for the discharge may be of the order of one millisecond. The operating time for relay 38 will generally be sufiicient to allow capacitor 70 to discharge, inasmuch as a conventional relay has an operating time of several milliseconds.

The time sequence of the switching circuit of the present invention is as follows. Assuming the modulator to be in operation as shown in the figure, switching from pulse forming network 20 to network 22 is effected by manually closing switch 86. The closing of switch 86 causes relay 36 to pull-in which, in turn, causes relay 34 todrop out. The deenergization of relay 34 removes the excitation from rectifier 12, connects capacitor 80 to thyratron 24 through resistor 82, thereby rendering thyratron 24 conducting so as to discharge capacitor 70 of filter circuit 14 and, in addition, to cause relay 38 to pull iti. When relay 38 is energized, it effects the disconnecting of pulse forming network 20 and pulse generator 30 from the modulator circuit and connects pulse forming network 22 and pulse generator 32 by the energization of relays 40 and 42, respectively. Simultaneously with this switching sequence, the energization of relay 38 alsol causes relay 34 to pull in again which reapplies excitation to rectifier 12 and disconnects capacitor 80 from thyratron 24, thus putting the modulator back in operation with pulse forming network 22 and pulse generator 32.

At the completion of the switching cycle from pulse forming network 20 to pulse forming network 22, all the relays are in an energized position. Pulse forming network 22 operates in the same manner as does network 20, the only difference being that it produces a pulse of longer time duration.

In switching back from pulse forming network 22 to pulse forming network 20 by opening switch 86, a similar sequence of steps isperformed, hence, tion need not be repeated.'

What is claimed as new is:

l. In a line-type modulator of the type which includes first and second pulse forming networks having a common junction, a source of periodic pulses, a filter circuit having a shunt capacitor, means for applying a unidirectional potential to said filter circuit, a charging inductor connected between said filter circuit and said first pulse forming network for charging said first pulse forming network to a high potential, a load impedance element, and a thyratron coupled to said source of periodic pulses, said thyratron being connected in series with said load impedance element between saidA first pulse forming network and said common junction for discharging said first pulse forming network through said load impedance element in response to said periodic` pulses; a circuit for switching the pulse forming networks comprising rst means for rendering said thyratron conductive for a predetermined time commencing at a desired instant of time, and for substantially simultaneously` removing said unidirectional potential from said filter circuit to discharge said shunt capacitor, first switching means operable a predetermined time after said desired instant of time for switching said charging inductor from said first pulse forming network to said second pulse forming network, and second switching means operable after the operation of said first switching means for re.- applying said unidirectional potential to said filter circuit.

2. The circuit defined in claim 1 wherein said first means includes a capacitor connected in series with a resistor, and means for charging said capacitor before said desired instant of time to a voltage that exceeds the ionization potential of said tyratron.

3. The circuit defined in claim 2 wherein said resistor and said capacitor have a time constant of sufhcient magnitude to enable current iiow through said charging inductor and said thyratron to commence, subsequent to said desired instant of time.

4. In a line-type modulator of the type which includes first and second pulse forming networks having a common junction, first and second pulse generators for producing triggering pulses having different repetition rates, a filter circuit having a shunt capacitor, means for applying a unidirectional potential to said filter circuit, a charging inductor connected between said filter circuit and said rst pulse forming network for charging said first pulse forming network to a high potential7 a load impedance element, and an electronic switch coupled to said first pulse generator and connected in series with said load impedance element between said first pulse forming network and said common junction for discharging said first pulse forming network through said load impedance element in response to said triggering pulses; a circuit for switching the pulse forming networks comprising automatically operable relay means including first switching means and a source of voltage for rendering said electronic switch conductive for a predetermined time and commencing at a desired instant of time, and for removing said unidirectional potential from said filter circuit to discharge said shunt capacitor, second switching means operable a predetermined time after said desired instant of time for switching said charging inductor from said first pulse forming network to said second pulse forming network and for switching said electronic switch from said first pulse generator to said second pulse generator, and third switching means automatically operable after the operation of said second switching means for reapplying said unidirectional potential to said filter circuit.

5. In a line-type modulator of the type which includes first and second pulse forming networks having a common junction, a source of periodic pulses, a filter circuit having a shunt capacitor, means for applying a unidirec` tional potential to said filter circuit, a charging inductor connected between said filter circuit and said first pulse the descripforming network for. charging said rstv pulse forming network to a"l1`i"g`h potential, a* load Yimpedance element, and a thyratron coupled to sa'id source, of periodic Apulses and Jconnected in series with ls'a'id 'load impedance elet.

ment 'between said firstzpulse'forming network and said common junction Vfor discharging saidirst pulse forming network' through said load impedance elementin response tosaidigpe'xiidic pulses; .a circuit for switching' .the pulse forming networks corngprising a storage capacitor connected' in ,series with a resistor, means 'for .charging said storage capacitor-Ato a yltage 'that exceeds the ionization potential of 'saidthyratrom rst switching meansy manually operable .at a desired instant offtime' for coupling said storagev capacitor to said'thyratron and for simultaneously removing said .unidirectional :potential ,from said'klter circuitto discharge 1saidstorage capacitor vthrough `said resistor; and said 'thyratrom 'thereby to l.discharge said shunt.o apacitor'olsaid lter. through said charging inductor;andsaidtthyratmn, Asecond switching meansautomatically operable .after vthe operation of said first switch, ing kmeansliorswitching said ,charging inductor from y'said rstgpulse forming network to. said second ,pulse formingnetwork, 1andthi1,d,switching means `automatically operable atiter .the 4operation =of `said second t switching means for..disconnecting :said storage ,capacitor ,from -said thyratronand lfor reapplyingsaid :unidirectional: -potential 'to saidillter circuit. l

6. .In .a line-typemodulator of. the type which ,includes rst-and,-secoridmulse forming ynetworks having a common junction, yaasource tof perodic' -pu1s.es,-a lter circuit having a shunt capacitor," means vfor applying a unidirectiona'lypotential' to said filterY circuit, a Icharging inductor connectedhetween 'saidfilter vcircuit and said rst pulse" forming ,network for. charging saidsrst p'ulseiforrx-i-V ingnetwork to"a\h'i gh"potential, a load impedance velement, andfa thyratron coupled to said source ofjper'iodic pulses and'connected in series'with said load impedance elementbetween said'rst pulse forming networkV an'clV sa'd common junction" for dischargingsaid iirstpu'lsc,Y forming network through said load impedance Aelenient in response to saidA periodic pu'lses5pa storage ycapacitor .connected in series with a resistor,V means for charging said storage capacitor to a voltage that exceedslthe ionization potential of said thyratron," ,first relay means for coupling `said storage -capacitor topsaid thyratron and for simultaneously removing ,said vunidirectional potential fromesaidlter circuit, second relay ,.rneans vrior 'switching said-charging inductor from ,sa'idlrst pulse forming network to' said second pulse torrrling. network,- third relay meansv for `disconnectingv said storage f capacitorl from said thyratrqn and'or reapplying'said unidirectional potential vto"sa id filter circuit, and means manually-operable at a"'desird'

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